Lecture 10

Question 1

What is mitosis?

Answer 1

The process going from one ‘mother cell’ to two identical ‘daughter cells’ (also identical to the mother cell)

Question 2

Why is mitosis needed?

Answer 2

• Growth
• Repair
• Cell replacement

Question 3

What are somatic cells?

Answer 3

Non-sex cells

Question 4

What are germline cells?

Answer 4

Sex-cells

Question 5

What is the result of meiosis?

Answer 5

From one cell to four non-identical sex cells

Question 6

Describe the cell cycle

Answer 6

• Interphase (G1, S, G2)
• Division: Nuclear division (mitosis), cellular division (cytokinesis)

Question 7

Describe what happens in each stage of the cell cycle

Answer 7

• G1 phase - cell content duplication
• S phase - DNA replication
• G2 phase - double check and repair
• M phase - mitosis
• Also G0

Question 8

What is the G₀ phase?

Answer 8

Stationary phase or quiescence phase

(comes off G₁ stage)

A cells will enter the G₀ phase if it doesn’t need to be replicated e.g. neurones after being created will stay in G₀ for the rest of its life, e.g. liver cells only divide again i.e. come out of G₀ when they are stressed, they then re-enter G₁ (growth factors required for this)

G₀ is either temporary or permanent

Question 9

How long does each stage in the cell cycle last?

Answer 9

1 full cell cycle lasts about 24 hours.

• G1 phase
• 10-12 hours
• S phase
• 6-8 hours
• G2 phase
• 3-4 hours
• M phase
  <1 hour

Question 10

What happens if the cell cycle is not controlled?

Answer 10

Can lead to cancer…

Question 11

Cell cycle control

Answer 11

Extremely complex, lots of factors are involved

Question 12

How many checkpoints are in the cell cycle?

Answer 12

3

Question 13

What controls the cell cycle?

Answer 13

Controlled by CDK/cyclin complexes.
CDK stands for Cycle Independent kinesis, there are proteisn that can phosphorylate other proteins. They are activated when paired up with cyclin

Question 14

Describe the control processes in the cell cycle

Answer 14

• G₁ checks for: cell size, nutrients, growth factors, DNA damage
• G₂ checks for: DNA damage, DNA replication completeness
• Mitosis: Checks if all chromosomes are properly attached to the mitotic spindles

Question 15

Why is DNA integrity important at a nucleotide and gene level?

Answer 15

Don’t want the code to be disrupted or damaged

Question 16

Why is DNA integrity important at chromosome level?

Answer 16

Important as chromosomes are passed from one generation to the next

Question 17

DNA integrity - could damage…

Answer 17

• Single strand damage (not as bad because the integrity of the molecule is not disrupted)
• Double strand damage (very genotoxic to the cell)

Question 18

How do DNA mechanisms fit in to DNA repair?

Answer 18

Most damage to DNA is recognised by the body, so is repaired making it healthy again.

However, if damaged DNA is not checked by:

• DNA repair mechanisms = mutation
• DNA repair mechanisms go wrong = mutation

Question 19

What in DNA can be damaged?

Answer 19

All components of the DNA molecule can be damaged:

• DNA base
• Sugar phosphate backbone
• Any strand
• Sugar

Question 20

What type of DNA damage could occur?

Answer 20

• Base missing
• Base is U instead of T
• Chemical base change
• Single strand break
• Bulky adducts (bulky bits added to DNA)
• A chemical structure that shouldn’t be there is there
• Cross-link
• Double stranded break
• Insertion
• Deletion

Question 21

DNA damage (two types of sources)

Answer 21

• Exogenous sources
• Endogenous sources

Question 22

List examples of exogenous sources and what is the definition of this?

Answer 22

​• ionising radiation
• UV
• alkylating agents
​• mutagenic chemicals
• anti-cancer drugs
• free radicals

Question 23

List examples of endogenous sources

Answer 23

Endogenous substances and processes are those that originate from within a system such as an organism, tissue, or cell.

• free radicals
• replication errors

Question 24

Why are free radicals endogenous source?

Answer 24

• Mitochondria creates free radicals
• Inflammation creates free radicals

Question 25

What can free radicals do?

Answer 25

Free radicals cell damage DNA

Question 26

What DNA damage could occur?

Answer 26

• Up to one million molecular lesions damaged per cell per day
• Apurinic site
• Deamination
• Mismatches
• Pyrimidine dimer
• Double stranded breaks
• Intercalating agent
• Interstrand crosslink
• Bulky adduct
• Single-strand break

Question 27

Define DNA replication stress

Answer 27

Replication stress = Inefficient replication that leads to replication fork slowing, stalling and/or breakage

Replication stress - when replication goes wrong

Question 28

3 main groups of DNA replication stress

Answer 28

1. Replication machinery defects
2. Replication fork progression hindrance
3. Defects in response pathways

Question 29

1. Replication machinery defects

Answer 29

What could go wrong?

• DNA polymerase
• DNA ligase
• Topoisomerase
• DNA helicase
• DNA primase

Question 30

Replication machinary defects could lead to…

Answer 30

Misincorporation and proofreading

• e.g. If DNA polymerase ability to proof-read prevents lots of mutations, DNA polymerase checks and realises it has done the wrong thing (proof-reading), it takes away the wrongly incorporated base, then puts in the right base and continues.
  DNA polymerase is working correctly, it will make a mistake 1 in 1 million times, DNA polymerase makes it 1000 times more efficient (therefore, it will still make mistakes)

Question 31

2. DNA replication fork progression hindrance (another replication stress)

What could hinder the progression of replication fork?

Answer 31

• Limited nucleotides
• DNA lesions (diamer forms)
• Fragile sites
• RNA nucleotide inclusion (U instead of T)
• DNA loops
• Transcription taking place (instead of DNA replication
• Repetitive DNA

Question 32

Repetitive DNA - How does this occur?

Answer 32

Fork slippage - leads to adding or removing of 1 base

Question 33

What are the two scenerios in fork slippage

Answer 33

• Scenerio 1: An extra ‘A’ nucleotide has been synthesised in a competitive area. Therefore, there is now a ‘bulge’ in the new strand, where there is an extra nucleotide
• Scenerio 2: Can get the same situation in the template strand, this means that the newly synthesised strand will be missing 1 nucleotide

Both are called fork slippage

Question 34

Fork slippage - Backward slippage

Answer 34

Question 35

Fork slippage - Forward slippage

Answer 35

Question 36

What happens in Huntington’s?

Answer 36

Backward slippage

Fork slippage can lead to trinucleotide (3 bases together - CAG, CAG, CAG, CAG, CAG, addded in) expansion e.g. Huntington’s, spinocerebellar ataxia, Fragile X

In Huntington’s this backward slippage has occured over and over again

(Look at other flashcard too)

Question 37

Huntington’s disease - the types of repeats etc

Answer 37

Huntington’s Disease
• CAG repeats in HTT gene leading to polyglutamine repeats in Huntingtin protein
• Normal 6-39 repeats
• Disease 35-121 repeats

Question 38

What happens in Huntingtons (symptoms)

Answer 38

• Normal function of Huntingtin protein still unknown
• Mutant Huntingtin protein aggregates in neurons affecting mainly basal ganglia (causes degeneration of neurones)
• Progressive, late onset disease

Question 39

3. Defects in response pathways (DNA replication stress)

Answer 39

These are the pathways that ‘deals’ with all these mutations, e.g. helicase can ‘deal’ with the loops, if there are defects in the response pathway, this can also cause DNA replication stress

Question 40

Define DNA damage response

Answer 40

The DNA Damage Response (DDR) includes the cellular pathways that sense, signal and repair DNA damage

Question 41

Response to DNA damage response

Answer 41

Sensors (signals of damage can be sensed by sensor) -> transducers -> effectors (decide what should happen to the cell - e.g. death, permanent cell cycle arrest, senescene)

Question 42

What are the three outcomes of a mutation?

Answer 42

• Senescene
• Apoptosis
• Proliferation

Question 43

If DNA damage levels are too high or persist what is the DNA damage response?

Answer 43

• Senescene = permanent cell cycle arrest (it won’t divide anymore but will still have some function, cells in senescence die sooner)
• Apoptosis = cell death

But the body would rather repair DNA and maintain function

Question 44

If DNA damage levels are manageable, DNA repair will occur to maintain function

Answer 44

• Proliferation (DNA repair and cell cycle control will occur and then proliferation will occur)

Question 45

What does the body do during DNA repair? (i.e. slow down, quicken up cell cycle)

Answer 45

May need to slow down the cell cycle during DNA repair (put the cell cycle in temporary arrest whilst DNA repair is occuring)

• DNA repair can take place at any point in the cell cycle

Question 46

What are the 4 DNA repairs?

Answer 46

1. Base-excision repair (single-strand base repair)
2. Nucleotide-excision repair (single-strand base repair)
3. Mismatch repair (single-strand base repair)
4. Recombinant repair (when there is a double strand break)

Different types of DNA damage will have different types of DNA repair mechanism

Question 47

1. DNA repair: Base excision repair (something is wrong with the base)

Answer 47

In example below, U is incorporated instead of a C

Question 48

2. DNA repair: Nucleotide excision repair

Answer 48

Question 49

3. DNA repair: Mismatch repair

Answer 49

Question 50

Overall characteristics of a single strand break

Answer 50

(includes: base excision, nucleotide excision, mismatch repair)

• relatively simple
• many different mechanisms
• integrity of the DNA molecule intact
• ‘damage’ removed on one strand only
• homology of other strand used to repair the damage on the damaged strand
• not error-free, but not error-prone either (normally successful as it uses the other strand as a template - as DNA has stayed intact on this strand

Question 51

4. DNA repair: Double strand break

Characteristics of this

Answer 51

• complex
• integrity of the DNA molecule lost (loss of DNA integrity)
• more likely error-prone, as not sure if putting the ‘right’ bits together
• use of homology may be possible

Question 52

Which two ways can a double strand break be repaired?

Answer 52

1. Non-homologous end joining
2. Homologous-directed repair

Question 53

What is non-homologous end joining (in DNA repair)

Answer 53

Non-homologous end joining

• broken ends recognised and protected
• complex formed and damaged ends removed (so cut a bit of the double strand ends)
• broken ends ligated (ends put back together)
• error-prone (it is much better to have a mutation (usually) than having a double stranded break. It is error-prone as don’t know if the right bits are being stuck together, always some removal of DNA)

Question 54

What is homologous-directed repair

Answer 54

Homologous-directed repair

1. Remove some of the strands, leaving overhangs in both strands
2. The intact DNA strands forms a bubble
3. The overhand then ‘invades’ the other DNA helix. The bits circled are complementary as they are joining up
4. By invading the other DNA helix, it can then remake the DNA using the other homologous DNA molecule, repairing it perfectly
   (do not need to know any more details than this)

Ends up with a perfect repair
It uses the other homologous chromosome to make the repair.
This is much better as it is much less risk prone, but if the cell does not have machinary available for the homologous-directed repair, non-homologous end joining will occur (non-homologous end joining hopes for the best that it will not cause a problematic mutation)

Question 55

Overview of both double stranded repair types

Answer 55

• Non-homologous end joining
• Homologous-directed repair

Question 56

Have an understanding that both non-homologous (NHEJ) end joining and homologous-directed repair (HR) occur more at different parts of the cell cycle

Answer 56

Question 57

Three main causes of cancer

Answer 57

1. Loss of cell cycle control
2. Accummulation of mutations from DNA replication stress
3. DNA repair defects

Question 58

1. Cause of cancer - Loss of cell cycle control can lead to cancer

Answer 58

When the checkpoints don’t occur correctly

*learn these checkpoints

Question 59

What is the meaning of a multi-step cancer model?

Answer 59

Mutation accumulation - lots of mutations need to occur before cell becomes cancerous

Question 60

2. Cause of cancer - DNA replication stress stimulates carcinogenesis

Answer 60

Many mutations need to occur before a cell becomes cancerous

DNA replication stress -> induces mutations -> accumulation of mutations -> malignant cells

Question 61

Example of mutation accumulation

Answer 61

Don’t need to learn details in the picture!

Question 62

DNA damage response are meant to prevent carcinogenesis (e.g. DNA repair mechanisms like base excision etc)

Answer 62

Question 63

3. Cause of cancer - DNA repair defects stimulate carcinogenesis

Answer 63

e.g. causes by DDR defect, mutated gene, syndrome, cancer predisposition

Remember DNA repair mechanisms include:

• Base excision repair
• Mismatch repair
• Non-homologous end joining
• Single strand break repair
• Nucleotide excision repair
• Homologous dependent repair
• Double strand break repair

(lots of others too, but the above list is what I need to learn)

Question 64

What is tumour heterogeneity?

Answer 64

Tumour heterogeneity describes the observation that different tumour cells can show distinct morphological and phenotypic profiles, including cellular morphology, gene expression, metabolism, motility, proliferation, and metastatic potential. This phenomenon occurs both between tumours and within tumours.

For example, the tumour attached is made up of 3 different sub-clones

Question 65

Cancer evolution

Answer 65

The tumour at the end looks very different from the tumour at the beginning (look at the attached picture, to show a tumour timeline)

Question 66

What does clonal expansion mean?

Answer 66

Multiplication or reproduction by cell division of a population of identical cells descended from a single progenitor. In immunology, may refer to the clonal proliferation of cells responsive to a specific antigen as part of an immune response

(the first step shows clonal expansion in the picture attached)

Question 67

What is the clonal expansion model?

Answer 67

Heterogenous tumours contain lots of different cancer clones. The make up of the tumour is changing all of the time, because:

• cells are still mutating
• when new cancer cells of a different type form, they are also competing for nutrients and oxygen etc. If they are better at getting these compared to antoehr cancerous clone, they outcompete the other clone. This will cause the ‘less efficient’/’less resourceful’ clone to die and the more resourceful/better competitor to continue multiplying and increasing in numbers.
• *This leads to the clonal expansion model**

Question 68

Chemotherapy - how does this change the tumour?

Answer 68

The tumour exists of many subclones, each subclone has a different sensitivity to the chemotherapy. (In the diagram attached, can see that chemotherapy is very effective against the red clone as it has reduced in size, however, the purple clone is resistant to chemotherapy). The blue clone keeps proliferating and the tumour comes back = differential sensitivity.

Question 69

Chemotherapy - how can these sometimes induce mutagenesis?

Answer 69

By trying to kill the cancer through chemotherapy, chemotherapy may actually induce more mutations, e.g. in the diagram attached, one of the red clones has mutated into a black clone which is resistant against chemotherapy

Question 70

Synthetic lethality strategies

Answer 70

The concept of using synthetic lethality as a therapeutic strategy in cancer: Looking at the diagram below, the loss of gene A or gene B in isolation is compatable with cellular viability (i.e. the cell will survive), however, if both genes are not functional, the cell will die. The diagram attached shows that in the cancer cell, gene B is mutated as part of the cancer anyway, the third cell across shows that it is surviving as gene A is still functional. However, gene A has been targetted by medication, this has now stopped both gene A and gene B from being functional in the cancer, but as only gene B is non-functional in the healthy cell, it can still survive (as it has gene B).